RU2518477C2 - Lever-type switching device - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: lever-type switching device contains: limiting partition (49) which is formed between the first and the second arms (19, 23) and limits displacement of the first and the second arm (19, 23) preventing rotation of the first and the second levers (13, 15) relative to moveable element (31); and engaging walls (45a, 45b, 47a, 47b) which are formed on the first and the second connecting portions (45, 47) and are engaged with the first and the second arms (19, 23) when the first and the second arms (19, 23) are rotating in result of rotation of the first and the second levers (13, 15) shaft to cause the first and the second plates (41, 43) to perform contact action.

EFFECT: trouble-free performance of lever-type undersized switching device.

5 cl, 11 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a lever switching device for contact adjustment of headlights of a vehicle.

State of the art

A conventional lever switching device is a lever switching device shown in FIGS. 10 and 11. FIG. 10 shows an exploded lever switching device, wherein parts interconnected during assembly are shown in perspective, and FIG. 11 is a sectional view of the lever a switching device, which shows the periphery of the switching unit.

The lever switching device 101, shown in FIGS. 10 and 11, is intended to supply an electric control signal and provides, for example, switching a turn signal, briefly switching on the main beam headlights, switching the main beam headlamps and low beam headlights or switching the headlights, and switching on and turning off the wiper and washer.

The lever switching device 101 comprises an adjustment knob 103 and a switching unit 105, the switching unit 105 being mounted on the side of the housing 106, which is mounted on the steering column 104.

The adjusting knob 103 comprises first, second and third levers 109, 107, 111.

The first lever 109 comprises a rotary button 112, which is mounted on one end of the lever, and a first control rod 113, which is mounted on the other end of the lever. The second lever 107 includes a stationary button 114, which is installed on one end of the lever, and a tubular locking element 115, which is installed on the other end of the lever and is an integral part thereof. On the tubular locking element 115, a second control rod 117 is provided.

The third lever 111 is rotatably mounted around the periphery of the first lever 109 and at its distal end comprises a third control rod 119.

In addition, the lever switching device 101 comprises a ratchet spring 121 and a snap element 123.

The movable member 127 of the switching unit 105 is housed in the housing 125 and rotatably supported on the shaft 127a. Said movable element 127 comprises a fourth control rod 129. The first lever 109 is rotatably supported by the movable element 127 on the shaft 107a. An electrode plate 131 is disposed in a lower portion of the housing 125. A plurality of fixed contacts are provided on the upper surface of the electrode plate 131. Above the electrode plate 131 are the first movable plate 133, the second movable plate 135, the third movable plate 137 and the fourth movable plate 139. The first, third and fourth movable plates 133, 137, 139 are able to move in a straight line in the direction that intersects the axis of the adjusting knob 103 ( for clarity, it should be noted that the indicated direction forms a right angle with the surface of the sheet on which the drawing is made, Fig. 11). The second movable plate 135 is able to move rectilinearly in the direction of the axis of the handle (from left to right, 11).

When the first movable plate 133 is moved rectilinearly, the headlights are turned on and off. When the second movable plate 135 is moved rectilinearly, switching between the main beam headlamps and the low beam headlamps and the high-beam headlamps turn on briefly. With a rectilinear movement of the third movable plate 137, the fog lights are turned on and off. When the fourth movable plate 139 is linearly moved, the direction indicator lamps turn on and blink.

On the first, third and fourth movable plates 133, 137, 139, corresponding engagement portions 141, 143, 145 are provided to facilitate linear movement of the first, third, and fourth movable plates 133, 137, 139, and a hole portion 147 is provided on the second movable plate 135 .

In addition, for example, when the first lever 109 is manipulated by the rotary button 112 to rotate it about an axis, the first control rod 113 is forcibly moved and occupies an articulated position. The first control rod 113, in contact with the engaging portion 141, exerts a force, as a result of which the first movable plate 133 moves in a direction that intersects the direction of the handle axis. Moving the first movable plate 133 causes the headlights to turn on and off. The third movable plate 137 moves in a similar manner with an adjustable rotation of the third lever 111 about its axis.

When the adjusting knob 103 is manipulated by turning it around the shaft 107a, in order to switch between the main beam headlamps and the low beam headlamps and to briefly turn on the main beam headlamps to give a signal, the second movable plate 135, by means of the second control rod 117, moves linearly in the direction axis of the handle.

At the same time, the first control rod 113 and the third control rod 119 are moved toward the engaging portions 141, 143 of the movable plates, whereby the first and third movable plates 133, 137 are not moved.

When the adjusting knob 103 is manipulated by turning it around the shaft 127a to turn on the turn lamps in a blinking mode, the fourth movable plate 139, by means of the fourth control rod 129, moves linearly in a direction that intersects the axis of the handle.

At the same time, the first and third control rods 113, 119 move in a direction that intersects the axis of the control lever (for clarity, it should be noted that this direction forms a right angle with the surface of the sheet on which the drawing is made) so that the engagement of the first and third control rods 113, 119 with sections 141, 143 of engagement of the movable plates. However, the first and third control rods 113, 119 are not engaged with the engaging portions 141, 143 of the movable plates, since there is a gap between them in the indicated direction, and therefore the first and third movable plates 133, 137 do not move.

In this way, various control levers can function smoothly.

However, according to the previously described design, a large distance must be provided between the center of the shaft 127a and the third control rod 119, which is located behind the axis of the handle, and they must be sufficiently spaced to prevent mutual interference of the first control rod 113 with the first movable plate 133 (section 141 engagement) and the third control rod 119 with the third movable plate 137 (engaging portion 143) that may occur when manipulating the adjusting handle 103 to rotate around Ala.

The disadvantage of this design is the need to increase the width of the switching unit 105 in the direction of the axis of the lever.

In addition, since the third control rod 119 is distant from the center of the shaft 127a by a large distance, when manipulating the adjusting knob 103 to rotate it around the shaft 127a, said third control rod 119 moves rectilinearly a large distance in the direction that intersects the direction of the axis of the handle (in the direction which intersects the surface of the sheet of paper on which the drawing is made at right angles), compared with the case when the third control rod 119 is located near the center of the shaft 127a.

Thus, since the third control rod 119 is distant from the center of the shaft 127a by a large distance, the third control rod 119 is moved to allow the third movable plate 137 to be connected to the fixed contact, or to disconnect the stationary contact from the third movable plate 137, which is actuated during adjustment the rotation of the third lever, goes a long distance. Therefore, it is likely that with the controlled rotation of the third lever 111, the stable contact action of the third movable plate 137 is not ensured.

In this case, in order to ensure the contact action of the third movable plate 137 during the regulating rotation of the third lever 111, the possibility of extending the third control rod 119 moving the third movable plate 137 is considered. However, the disadvantage of this configuration is the need to increase the height of the switching unit 105 in the vertical direction (if we consider FIG. eleven).

Patent Literature 1: JP-A-11-250772

Disclosure of invention

The increased size of the lever switching device according to the prior art is a disadvantage that must be addressed.

In order to reduce the size of the described lever switching device according to the prior art, a lever switching device according to the invention is proposed, comprising a movable element that is rotatably supported in the housing, first and second movable plates, which are arranged to move along an electrode plate mounted on one of sides of the housing, in a direction that intersects the center of rotation of the movable element at a right angle, and force The action with respect to the electrode plate, as well as containing the first and second levers, which are supported with the possibility of free swinging movement and rotation, while they are located so that they can coaxially rotate around its axis on the movable element, characterized mainly by which contains the first and second connecting sections, which are provided on the first and second movable plates and are located adjacent in the transverse direction relative to the center of rotation of the movable element, the first shoulder and second e shoulder, the near sections of which are supported on the first and second levers, while the shoulders can rotate around their axial centers located at right angles to the axes of the first and second levers, can rotate along the axes of the levers, but cannot rotate around the axes of the levers, end sections of the first shoulder and second shoulder are installed in the first and second connecting sections and are adjacent in the transverse direction relative to the center of rotation of the movable element, and contains a restrictive partition, which is formed between the first shoulder and the second shoulder and keeps the first shoulder and second shoulder from moving in the direction of the axis of the lever depending on the rotation of the first and second levers relative to the movable element, and the engaging partitions that are formed on the first and second engagement sections so that as a result of the rotational movement of the first and second arms by axial rotation of the first and second levers, the first and second arms were engaged with the engaging portions of the movable plates first and second movable plates forcibly performed contact action.

The present invention allows to reduce the size of the lever switching device due to the fact that in the construction described above, the distal end sections of the first and second arm, by which the first and second arms are installed in the first and second connecting sections, can be located close to the axis of rotation of the movable element.

Brief Description of the Drawings

Figure 1 - lever switching device in disassembled form, and interconnected during assembly of the parts shown in perspective (option 1 embodiment of the invention).

Figure 2 is a sectional view of the control lever and the switching unit (preferred embodiment of the invention).

Figure 3 is an enlarged sectional view of the main part of the device (embodiment 1 of the invention).

4 is a perspective view of the main part of the device, with the housing cover removed (preferred embodiment of the invention).

5 is a bottom view of the main part of the device with the electrode plate installed, the lower protective panel being removed (embodiment 1 of the invention).

6 is a bottom view of the main part of the device with the electrode plate, with the lower protective panel and the second movable plate removed (option 1 embodiment of the invention).

7 is a bottom view of the main part of the device with the electrode plate, with the lower protective panel and the first movable plate removed (option 1 embodiment of the invention).

Fig. 8 is a perspective view of a portion of a lever switching device viewed from the side of the first and second levers, showing the relationship of the first arm and the first movable plate (Embodiment 1).

Fig.9 is a perspective view of a section of a lever switching device viewed from the opposite side with respect to the first and second levers, which shows the relationship of the first shoulder and second shoulder with the second movable plate (embodiment 1 of the invention).

Figure 10 - lever switching device in disassembled form, and interconnected during assembly of the parts shown in perspective (prior art).

11 is a view in section of a lever switching device, which shows the periphery of the switching unit (prior art).

The implementation of the invention

The objective of the present invention to reduce the size of the lever switching device is solved thanks to the lever switching device containing the first and second connecting sections, which are provided on the first and second movable plates and are located adjacent in the transverse direction relative to the center of rotation of the movable element, the first shoulder and second shoulder, proximal sections which are supported on the first and second levers, while the shoulders can rotate around their axial centers located under the direct gloom to the axes of the first and second levers, can rotate along the axes of the levers, but can not rotate around the axes of the levers, and the distal end sections of the first shoulder and second shoulder are installed in the first and second connecting sections and are adjacent in the transverse direction relative to the center of rotation of the movable element, and comprising a restrictive partition that is formed between the first shoulder and the second shoulder and holds the first shoulder and second shoulder from moving in the direction of the axis of the lever depending on rotation I of the first and second levers relative to the movable element, and the engaging partitions, which are formed on the first and second parts of the engagement so that as a result of the rotational movement of the first and second arms by axial rotation of the first and second levers, the first and second arms are engaged with the engagement sections movable plates and the first and second movable plates forcibly performed contact action.

Embodiment 1 of the Invention

Schematic diagram of a lever switching device

The lever switching device according to Embodiment 1 of the invention is shown in FIG. 1 in a disassembled form, wherein the parts interconnected during assembly are shown in perspective.

The lever switching device 1, shown in FIG. 1, is designed to supply electrical control signals and provides, for example, switching a turn signal, briefly switching on the main beam headlights, switching between the main beam headlamps and the low beam headlamps or switching the headlights.

The lever switching device 1 contains control knobs 3, 5 and switching blocks 7, 9, and the switching blocks 7, 9 are mounted on the side of the housing, which is mounted on the steering column.

Next, the adjustment knob 3 and the switching unit 7 according to the indicated embodiment will be described in detail

Figure 2 shows a sectional view of the control knob and the switching unit, and figure 3 shows an enlarged sectional view of the main part of the device.

As shown in figure 1, the adjusting knob freely rotates in the directions indicated in the drawing by arrows A, B (in the direction of rotation of the steering wheel) and in the directions indicated in the drawing by arrows C, D (in the direction of the steering column).

The adjusting knob 3 provides, for example, switching the turn signal and, therefore, when the handle is manipulated in the direction indicated by arrow A or B in the drawing, a flashing turn signal is turned on. The adjusting knob 3 also provides, for example, a short-time activation of the main beam, i.e. when the handle is manipulated, moving it to the extreme position in the direction indicated by arrow C in the drawing, the headlights briefly turn on. The adjusting knob 3 also provides, for example, switching between the main-beam headlamps and the low-beam headlamps or switching the headlamps, i.e. when the handle is manipulated in the direction indicated by the arrow C or D in the drawing, switching between the high beam headlamps and the low beam headlamps occurs. The adjusting knob 3 provides, for example, turning the headlights on and off. When they manipulate, for example, the first rotary button 10, the headlights and marker lights turn on and off, and when they manipulate, for example, the second rotary button 12, the fog lights turn on and off.

The adjusting knob 3 comprises a first lever 13 and a second lever 15, which is hollow, so that the first lever 13 enters the second lever 15 and they are arranged concentrically. The first and second levers 13, 15 are control shafts moving the movable plates along the electrode plate, as will be described later. It should be noted that the first and second levers 13, 15 are arranged concentrically with respect to the third lever 16.

The first rotary button 10 by means of a ratchet mechanism 17 is mounted on one end of the first lever 13 and the first shoulder 19 is mounted on the other end of the first lever 13. The second rotary button 12 is mounted on one end of the second lever 15 and the second shoulder 23 is mounted on its other end.

The switching unit 7 has a housing 25 on which a cover 27 is properly secured from above. As shown in FIG. 2, a partition wall 29 is provided inside the housing 25, and a movable member 31 is located on one side of the partition wall 29. The shaft 33 is rotatably mounted on an end portion of the movable member 31 on the housing cover 27. The adjusting knob 3 is rotatably mounted and, by means of a shaft 35 formed on the third lever 16, rotates relative to the movable element 31 in the direction indicated by arrow C or D.

The center of rotation of the movable member 31 is the pivot axis of the adjusting knob when the pivot switch is actuated, which is indicated in the figure by P T / S.

The electrode plate 37 is located under the dividing wall 29. On the upper surface of the electrode plate 37 there are many fixed contacts. Electronic devices, such as diodes, are mounted on the lower surface of the electrode plate 37. On the underside of the electrode plate 37, a lower protective panel 39 is mounted.

The first movable plate 41 and the second movable plate 43 are located above the electrode plate 37 and under the dividing wall 29. The first and second movable plates 41, 43 are arranged so that they are able to move linearly and parallelly in a direction that corresponds to the direction of movement of the steering wheel (in FIG. 2 and 3 direction at right angles to the surface of the sheets of paper on which the drawings are made).

When the first movable plate 41 moves rectilinearly, the headlights turn on and off, and when the second movable plate 43 moves rectilinearly, the fog lights turn on and off.

The first and second shoulders and the first and second movable plates

Figure 4 shows a perspective view of the main part of the lever switching device, and the housing cover and the movable element are removed. Figure 5 shows a bottom view of the main part of the lever switching device, and the electrode plate and the lower protective panel are removed. Figure 6 shows a bottom view of the main part of the lever switching device with the electrode plate, with the lower protective panel and the second movable plate removed. 7 shows a bottom view of the main part of the lever switching device with the electrode plate, with the lower protective panel and the first movable plate removed.

As shown in FIGS. 3-7, the first and second connecting portions 45, 47 are formed entirely on the first and second movable plates 41, 43, respectively. The first and second connecting sections 45, 47 are arranged so that relative to the first and second movable plates 41, 43 they are offset from the axis of rotation (P T / S).

The first and second connecting sections 45, 47 are in the form of an open box. As shown in FIGS. 8 and 9, both side walls of the first and second connecting portions 45, 47 form the first and second engaging partitions 45a, 45b, 47a, 47b in the direction in which the first and second movable plates 41, 43 move rectilinearly.

The first and second connecting sections 45, 47 are in the form of an open box, which is formed by three walls, i.e. the first and second engaging partitions 45a, 45b, 47a, 47b and the walls 45c, 47c, the open sides of the connecting sections facing the restrictive partition 49 formed in the housing 25, and the first and second connecting sections 45, 47 are located next to each other. The walls 45c, 47c are located at a certain distance and face the restrictive partition 49.

It should be noted that the restrictive partition 49 can be formed entirely on any of the connecting sections, i.e. in the first or second connecting portions 45, 47 or a restrictive partition 49 may be formed in both the first and second connecting portions 45, 47.

Thus, the first and second connecting sections 45, 47 are located next to each other and between them there is a restrictive partition 49.

The first and second distal end sections 19a, 23a of the first and second arm 19, 23 are mounted on the first and second connecting sections 45, 47.

The restriction partition 49 is located on the pivot axis (P T / S) of the movable member 31 between the first and second arms 19, 23. The restriction partition 49 restricts the movement of the first arm 19 and the second arm 23 relative to the movable member 31 due to rotation (rotation in a direction corresponding to the direction steering column) of the first and second levers 13, 15 around the shaft 35.

On Fig presents a perspective view of a lever switching device, viewed from the side of the first and second levers, which shows the relationship between the first shoulder and the first movable plate. Figure 9 shows a perspective view of a lever switching device viewed from the opposite side with respect to the first and second levers, which shows the relationship of the first shoulder and second shoulder with the second movable plate.

As shown in FIGS. 3 and 8, the first shoulder 19 is formed of two sections, namely, the first proximal frame-shaped portion 19b and the first distal portion 19a, which are integral. At the first distal end portion 19a of the first arm 19, a first hemispherical portion 19c is formed that is cut off on a side facing the second distal end portion 23a of the second arm 23. The side of the first distal end portion 19a that is adjacent to the second distal end portion 23a of the second shoulder 23 and contains a first hemispherical portion 19c, forms a flat section 19d. The specified flat section 19d faces the bounding wall 49 in the transverse direction relative to the axis of rotation (P T / S).

The first proximal portion 19b is in the form of a frame, and a rib 19ba is formed in its central part. Both the outer periphery of the distal end of the second lever 15 and the outer periphery of the distal end of the first lever 13 protruding from the second lever 15 are rectangular in shape, with slots 15a, 13a being made at the far ends of the levers 15 and 13.

The first proximal portion 19b of the first arm 19 is located at the distal end of the first arm 13, and the rib 19ba enters the slot 13a. Mounting the first arm 19 on the first arm 13 in this manner prevents the rotation of the first arm 19 about the axis of the first arm 13.

The first proximal portion 19b of the first arm 19 is rotatably supported at the distal end of the first arm 13 by a hinge 19e.

The first shoulder 19 is mounted on the first lever 13 with the possibility of rotation along the axis of the first lever 13 through the hinge 19e, while the rotation of the first shoulder 19 about the axis of the first lever 13 can be prevented, since the first proximal portion 19b of the first shoulder 19 is mounted on the far end of the first lever 13 .

It should be noted that the rotation of the first arm 19 around the axis of the first arm 13 can only be prevented by the corresponding engagement of the first arm 13 with a hinge 19e mounted on the first proximal portion 19b of the first arm 19. However, there is a possibility of a violation of the corresponding engagement due to the load applied to the connecting portion therefore, a reliable way to prevent rotation of the first shoulder 19 is to force the rib 19ba into the slot 13a.

When the first arm 19 is mounted on the first arm 13 in the above manner, the first distal end portion 19a of the first arm 19 is installed in the first connecting portion 45. There is a gap between the first distal end portion 19a of the first arm 19 and the first engaging partitions 45a, 45b of the first connecting portion 45 the direction of rectilinear movement of the first movable plate 41.

As shown in FIGS. 3 and 9, the second arm 23, as well as the second connecting portion 47, are formed similarly to the first shoulder 19 and the first connecting portion 45.

The second arm 23 is formed of two sections, namely, the second proximate frame-shaped proximal portion 23b and the second distal end portion 23a, which are integral, the second proximal portion 23b mounted at the distal end of the second arm 15. At the distal end portion 23a of the second of the arm 23, a second hemispherical portion 23c is provided, which is located adjacent to the first distal end portion 19a of the first arm 19. The side of the second distal end portion 23a, which is located adjacent to the first distal end portion 1 9a of the first arm 19 and which contains the second hemispherical portion 23c, forms a flat section 23d located along the axis of rotation (P T / S).

The connecting portion of the second arm 23, which is mounted on the second arm 15, is located at a distance from the axis of rotation (P T / S). Where the second arm 23 is mounted on the second arm 15, the connecting portion of the second arm 23 is bent and substantially V-shaped in cross section, toward the far end of the second arm 15, whereby the distal end portion 23a of the second arm 23 is located in the connecting portion 47 of the second movable plate 43 and occupies a position adjacent to the axis of rotation (P T / S).

Therefore, both the first arm 19 and the second arm 23 can be installed in the connecting sections 45, 47 of the movable plates 41, 43 and occupy a position near the axis of rotation (P T / S). In addition, the first shoulder 19 and the second shoulder 23 can be located essentially at the same distance from the axis of rotation (P T / S).

With this mounting pattern, the rotation of the second arm 23 around the axis of the second arm 15 is prevented.

The second proximal portion 23b of the second arm 23 is mounted at the distal end of the second arm 15 rotatably by a hinge 23e.

The second arm 23 is mounted on the second arm 15 with the possibility of rotation along the axis of the second arm 15 by the hinge 23e, while the rotation of the second arm 23 around the axis of the second arm 15 can be prevented, since the second proximal portion 23b of the second arm 23 is mounted on the far end of the second arm 15 .

When the second arm 23 is mounted on the second arm 15 in the above manner, the second distal end portion 23a of the second arm 23 is installed in the second connecting portion 47. There is a gap between the second distal end portion 23a of the second arm 23 and the second engaging partitions 47a, 47b of the second connecting portion 47 the direction of rectilinear movement of the second movable plate 43.

Due to the shape of the hemispherical sections 19c, 23c, their uniform contact is ensured (point contact can be made) with the walls 45c, 47c, while the first and second arms 19, 23 can move when the adjusting handle 3 is manipulated in the direction indicated by arrow C or D.

According to the described construction, when manipulating the adjusting knob 3 and moving it in the direction indicated by arrow A or B in the drawing to turn on the flashing turn signal, the first and second distal end sections 19a, 23a of the first and second arm 19, 23 only slightly rotate around the axis of rotation (P T / S), relatively moving within a small gap in the first and second connecting portions 45, 47.

Thus, when the control knob 3 is manipulated to turn on the flashing turn signal, there is no coordination of the movement of the first and second movable plates 41, 43, as a result of which the first and second movable plates 41, 43 do not move linearly.

When the adjusting knob 3 is manipulated by moving it in the direction indicated by the arrow C or D in the drawing in order to switch between the main beam headlamps and the low beam headlamps, the first and second arms 19, 23 are engaged with the walls 45c, 47c of the first and second connecting sections 45, 47 and the restrictive partition 49, as a result of which the movement of the first and second shoulder 19, 23 is limited. Improper action can be prevented by restricting the movement of the first and second arm 19, 23 in this manner.

In this situation, the adjusting knob 3 can be easily manipulated in the direction indicated by the arrow C or D in the drawing, while the first and second movable plates 41, 43 do not apply reaction forces to the handle, since the proximal portions 19b, 23b of the first and second arm 19, 23 have the ability to rotate relative to the first and second levers 13, 15 by means of hinges 19e, 23e.

When the first rotary button 10 is manipulated, the first lever 13 rotates about its axis, and the first shoulder 19 rotates with it. When the first shoulder 19 is rotated in this way, the first distal end portion 19 a moves relative to the first connecting portion 45 by a distance that is larger than the gap as a result of which it engages with the first engaging partition 45a, 45b, forcing the first movable plate 42 to move in a straight line.

The rectilinear movement of the first movable plate 41 enables the headlights and position lamps to be turned on or off.

When the second rotary button 12 is manipulated, the second lever 15 rotates around its axis, and the second shoulder 23 rotates with it. When the second arm 23 is rotated in this manner, the second distal end portion 23a is moved relative to the second connecting portion 47 by a distance that is larger than the gap, resulting in engagement with the second engaging partitions 47a, 47b, causing the second movable plate 43 to move in a straight line.

The rectilinear movement of the second movable plate 43 enables the fog lights to be turned on or off.

Preferred Embodiment

According to a preferred embodiment of the invention, there is provided a lever switching device 1 comprising a movable element 31, which is rotatably supported in the housing 25, first and second movable plates 41, 43, which are arranged to move along an electrode plate 37 mounted on one side of the housing 25, in a direction that intersects the center of rotation of the movable element 31 at a right angle, and forcibly perform a contact action with respect to the electrode plate 37, and also containing the first and second levers 13, 15, which are supported with the possibility of free rotation, while they are located so that they can coaxially rotate around its axis on the movable element 31, characterized in that it contains the first and second connecting sections 45, 47, which are provided on the first and second movable plates 41, 43 and are located near and in the transverse direction relative to the center of rotation of the movable element 31, the first arm 19 and the second arm 23, the adjacent sections 19b, 23b of which are supported on the first and second growling ax 13, 15, while the shoulders can rotate around their axial centers located at right angles to the axes of the first and second levers 13, 15, can rotate along the axes of the levers, but can not rotate around the axes of the levers, and the far end sections 19a, 23a the first and second arm 19, 23 are installed in the first and second connecting portions 45, 47 and are located adjacent in the transverse direction relative to the center of rotation of the movable element 31, and contains a restrictive partition 49, which is formed between the first arm 19 and the second 23 and holds the first shoulder 19 and the second shoulder 23 from moving in the direction of the axis of the lever depending on the rotation of the first and second levers 13, 15 relative to the movable element 31, and the engaging partitions 45a, 45b, 47a, 47b that are formed on the first and second sections 45, 47 of the engagement, so that as a result of the rotational movement of the first and second arm 19, 23 by axial rotation of the first and second levers 13, 15, the first and second arm 19, 23 are engaged with the engagement sections 45, 47 of the movable plates and the first and second by Vision plates 41, 43 force the contact action performed.

Thus, since the first and second distal end portions 19a, 23a, by which the first and second arms 19, 23 are mounted in the first and second connecting portions 45, 47, and are located close to the pivot axis (P T / S), it is possible to reduce the width of the switching unit 7 in the axial direction of the adjusting knob 3.

In addition, since the first and second distal end portions 19a, 23a, by which the first and second arms 19, 23 are mounted in the first and second connecting portions 45, 47, and are located close to the pivot axis (P T / S), there is no need increasing the length of the control rod in the lever switching device according to the invention compared to the lever switching device according to the prior art, moreover, since the first and second movable plates 41, 43 perform a contact action in combination with axial adjustment by turning the first and second levers 13, 15 by means of the first and second rotary buttons 10, 12 when manipulating the adjusting knob 3 to adjust the rotation of the first arm 19 and the second arm 23 around the axis of rotation (P T / S), it is possible to reduce the width of the switching unit 7 in a direction that is at right angles to the axial direction of the adjusting knob 3.

On the first and second distal end sections 19a, 23a of the first and second shoulder 19, 23, the first and second hemispherical sections 19c, 23c, respectively, are made, which are cut off on the sides facing each other.

Due to this, the first and second distal end sections 19a, 23a can be located close to the axis of rotation (P T / S). In addition, when the adjusting handle 3 is manipulated in the direction indicated by the arrow C or D in the drawing, the first and second arms 19, 23 can act between the walls 45c, 47c, while the first and second arms 19, 23 can move, it should be noted that the adjusting knob 3 can be easily manipulated in the direction indicated by the arrow C or D in the drawing, while the first and second movable plates 41, 43 do not apply reaction forces to the knob 3.

The first and second connecting sections formed from the walls are facing the restrictive partition and are at a distance from each other.

Due to this, when the adjusting handle 3 is manipulated by moving it in the direction indicated by the arrow C or D in the drawing, the movement of the first and second arm 19, 23 is limited by the walls, which can prevent incorrect actions.

Namely, for example, when the adjusting handle 3 is manipulated in the direction indicated by the arrow D in the drawing, the wall prevents the first shoulder 19 from moving from the first connecting portion 45 in the direction of the lever axis. Thus, when the first rotary button 10 (adjusting knob 3) is manipulated under these conditions, turning it to the position of turning on the marker light, the first movable plate 41 is moved to ensure reliable switching on the marker lamps.

List of Reference Items

1 - lever switching device; 3, 5 - adjusting knob; 13 - the first lever; 15 - the second lever; 19 - the first shoulder; 19a - the far end section; 19b is the near section; 23 - the second shoulder; 23a - the far end section; 23b - the near section; 25 - case; 31 - movable element; 37 - electrode plate; 41 - the first movable plate; 43 - the second movable plate; 45 - the first connecting section; 45a, 45b - engaging partition; 45c - wall; 47 - the second connecting section; 47a, 47b - engaging partition; 47c - wall; 49 - restrictive partition; P T / S - axis of rotation.

Claims (5)

1. A lever switching device comprising:
a movable element that is rotatably supported in the housing;
the first and second movable plates, which are arranged to move along the electrode plate mounted on one of the sides of the housing, in a direction that intersects the center of rotation of the movable element at a right angle, and forcefully perform a contact action with respect to the electrode plate; and
the first and second levers, which are supported with the possibility of free swinging movement and rotation, while they are located so that they can coaxially rotate around its axis on a movable element, characterized in that it contains:
the first and second connecting sections, which are provided on the first and second movable plates and are located adjacent in the transverse direction relative to the center of rotation of the movable element;
the first shoulder and the second shoulder, the near sections of which are supported on the first and second levers, while the shoulders can rotate around their axial centers located at right angles to the axes of the first and second levers, can rotate along the axes of the levers, but cannot rotate around the axes of the levers moreover, the distal end sections of the first shoulder and the second shoulder are installed in the first and second connecting sections and are adjacent in the transverse direction relative to the center of rotation of the movable element;
a restrictive partition that is formed between the first shoulder and the second shoulders and holds the first shoulder and the second shoulder from moving in the direction of the axis of the lever depending on the rotation of the first and second levers relative to the movable element; and
engaging partitions that are formed in the first and second engagement sections so that as a result of the rotational movement of the first and second arm by axial rotation of the first and second levers, the first and second arms are engaged with the engaging portions of the movable plates and the first and second movable plates are forcibly performed contact action. 2. The lever switching device according to claim 1, characterized in that
hemispherical sections are formed at the distal end sections of the first and second shoulder, and hemispherical sections are cut off on the sides that face each other. 3. The lever switching device according to claim 1 or 2, characterized in that
the first and second connecting sections formed from the walls, and are located so that they are facing the restrictive partition and are at a distance from each other. 4. A lever switching device comprising:
a movable element that is supported to rotate in the housing;
a plurality of movable plates, which are arranged to move along an electrode plate mounted on one of the sides of the housing, in a direction that intersects the axial axis of the movable element at a right angle, and forcibly perform a contact action with respect to the electrode plate; and
many levers, which are supported with the possibility of free swinging movement and rotation, while they are located so that they can coaxially rotate around their axis on the movable element and by axial rotation force the movable plates to individually perform a contact action, characterized in that
many movable plates are arranged so that they overlap each other, at least partially. 5. The lever switching device according to claim 4, characterized in that it contains:
the connecting sections that are provided on the movable plates and are located laterally in the transverse direction relative to the axis of rotation of the movable element and the plurality of arms that are provided on the plurality of levers are installed along the axis of the levers, and characterized in that the connecting sections are located in an area where the movable plates are overlapped.

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